Abstract
The characteristics of the faunal community in the soil are closely related to soil quality and function. Land degradation, which reduces vegetation cover, may affect the soil surface-active fauna because both the above ground and below ground invertebrates depend on complex plant communities. In this study, we evaluated the effect of land degradation/restoration and factors affecting soil fauna in northern Iran. The studied land uses were virgin natural forest (VNF), Alnus subcordata C.A.M. plantation (ASP), Quercus castaneifolia C.A. Mey plantation (QCP), Cupressus sempervirens var. horizontalis plantation (CSP) and degraded natural forest (DNF). VNF and ASP enhanced soil earthworm density (2.43 and 2.12 ind. m−2) and dry mass (27.44 and 23.39 mg m−2) with more ratio of epigeic. The activities of acarina (91,851.37 and 85,810.43 ind. m−2), collembola (83,009.50 and 74,996.18 ind. m−2) and protozoa [921.25 and 851.81 (× 102 g soil)] were increased under VNF ≈ ASP, respectively. Nematode population (650 in 100 g soil) significantly improved under VNF. In general, good quality forest floor, alkaline soil and accumulation of macro-element nutrients improved biological activities under the VNF and ASP sites, while low-quality forest floor, acidic soil, less macro-elements nutrients decreased biological activities imposed by the QCP, CSP and DNF sites. More activities of the studied soil fauna were found in autumn and spring. The findings of this study support the importance of preserving natural forests. In addition, employing N2-fixing and suitable native broadleaved species have been proposed in a bid to rehabilitate DNFs.
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References
Allison LE (1975) Organic carbon. In: Black CA (ed) Methods of soil analysis, part 2. American Society of Agronomy, Madison, pp 1367–1378
Anonymous (2016) Forest management planning in Neirang district of Noshahr. Organization of Forest and Rangelands and Watershed Management, Tehran, p 297
Bandyopadhyaya I, Choudhuri DK, Ponge JF (2002) Effects of some physical factors and agricultural practices on Collembola in a multiple cropping programme in West Bengal (India). Eur J Soil Biol 38:111–117
Bayranvand M, Kooch Y, Rey A (2017a) Earthworm population and microbial activity temporal dynamics in a Caspian Hyrcanian mixed forest. Eur J Forest Res 136:447–456
Bayranvand M, Kooch Y, Hosseini SM, Alberti G (2017b) Humus forms in relation to altitude and forest types in the northern mountainous regions of Iran. For Ecol Manage 385:78–86
Bedano JC, Cant MP, Doucet MD (2005) Abundance of soil mites (Arachnida: Acari) in a natural soil of central Argentina. Zool Stud 44:505–512
Bedano JC, Cantu MP, Doucet MF (2006) Influence of three different land management practices on soil mite (Arachnida: Acari) densities in relation to a natural soil. Appl Soil Ecol 3:293–304
Behan-Pelettier VM (1999) Oribatid mite’s biodiversity in agro ecosystems: role for bio indication. Agric Ecosyst Environ 74:411–423
Birkhofer K, Diekötter T, Boch S, Fischer M, Müller J, Socher S, Wolters V (2011) Soil fauna feeding activity in temperate grassland soils increases with legume and grass species richness. Soil Biol Biochem 43:2200–2207
Blasi S, Menta C, Balducci L, Delia Conti F, Petrini E, Piovesan G (2013) Soil micro arthropod communities from Mediterranean forest ecosystems in Central Italy under different disturbances. Environ Monit Assess 185:1637–1655
Bower CA, Reitemeier RF, Fireman M (1952) Exchangeable cation analysis of saline and alkali soils. Soil Sci 73:251–262
Bremner JM, Mulvaney CS (1982) Nitrogen—total. In: Page AL et al (eds) Methods of soil analysis. Part 2. Chemical and microbiological properties. ASA, Madison, pp 595–624
Cassagne N, Gers C, Gauquelin T (2003) Relationships between Collembola, soil chemistry and humus types in forest stands (France). Biol Fertil Soils 37:355–361
Choi WL, Moorhead DL, Neher DA, Ryoo ML (2006) A modeling study of soil temperature and moisture effects on population dynamics of Paronychiurus kimi (Collembola: Onychiuridae). Biol Fertil Soils 43:69–75
Collignon C, Uroz S, Turpault MP, Frey-Klett P (2011) Seasons differently impact the structure of mineral weathering bacterial communities in beech and spruce stands. Soil Biol Biochem 43:2012–2022
Crumsey J, Le Moine JM, Vogel CS, Nadelhoffer KJ (2013) Historical patterns of exotic earthworm distributions inform contemporary associations with soil physical and chemical factors across a northern temperate forest. Soil Biol Biochem 68:503–514
Day A, Chaudhur PS (2014) Earthworm community structure of pineapple (Ananas comosus) plantations under monoculture and mixed culture in West Tripura, India. Trop Ecol 55:1–17
de Moraes J, Franklin E, de Morais JW, de Souza JLP (2011) Species diversity of edaphic mites (Acari: Oribatida) and effects of topography, soil properties and litter gradients on their qualitative and quantitative composition in 64 km2 of forest in Amazonia. Exp Appl Acarol 55:39–63
Dechoum MS, Zenni RD, Castellani TT, Zalba SM, Rejmánek M (2015) Invasions across secondary forest successional stages: effects of local plant community, soil, litter, and herbivory on Hovenia dulcis seed germination and seedling establishment. Plant Ecol 216:823–833
Edwards CA, Bohlen PJ (1996) Biology and ecology of earthworms, 3rd edn. Chapman and Hall, London
Elfstrand S, Lagerlöf J, Hedlund K, Mårtensson A (2008) Carbon routes from decomposition plant residues and living roots into soil food webs assessed with C labelling. Soil Biol Biochem 40:2530–2539
Erdmann G, Scheu S, Maraun M (2012) Regional factors rather than forest type drive the community structure of soil living oribatid mites (Acari, Oribatida). Exp Appl Acarol 57:157–169
Ferreira de Araújo AS, Eisenhauer N, Pinheiro Leal Nunes LA, Carvalho Leite LF, Cesarz S (2015) Soil surface-active fauna in degraded and restored lands of northeast Brazil. Land Degrad Dev 26:1–8
Ferris H, Griffiths BS, Porazinska DL, Wang KH, Tenuta M (2012) Reflections on plant and soil nematode ecology: past, present and future. J Nematol 442:115–126
Franco ALC, Knox MA, Andriuzzi WS, de Tomasel CM, Sala OE, Wall DH (2017) Nematode exclusion and recovery in experimental soil microcosms. Soil Biol Biochem 108:78–83
Ge P, Da LJ, Wang WB, Xu XN (2014) Seasonal dynamics of dissolved organic carbon, nitrogen and other nutrients in soil of Pinus massoniana stands after pine wilt disease disturbance. J Plant Nutr Soil Sci. https://doi.org/10.4067/S0718-951620104005000006
Grant JA, Villani MG (2003) Soil moisture effects on entomopathogenic nematodes. Environ Entomol 32:80–87. https://doi.org/10.1603/0046-225X-32.1.80
Hasegawa M (2001) The relationship between the organic matter composition of a forest floor and the structure of a soil arthropod community. Eur J Soil Biol 37:281–284
Heydari M, Poorbabaei H, Bazgir M, Salehi A, Eshaghirad J (2014) Earthworms as indicators for different forest management types and human disturbance in Ilam oak forest, Iran. Folia For Pol Ser A 56:121–134
Holly DC, Ervin GN, Jackson CR, Diehl SV, Kirker GT (2009) Effect of an invasive grass on ambient rates of decomposition and microbial community structure: a search for causality. Biol Invasions 11:1855–1868
Homer CD, Pratt PF (1961) Methods of analysis for soils, plants and waters. University of California, Agricultural Sciences Press, Berkeley, p 309
Hutson BR, Veitch LG (1987) Densities of Collembola and Acarina in the soil and litter of three indigenous South Australian forests related to layer, site and seasonal differences. Aust J Ecol 12:239–261
Ilieva-Makulec K, Olejniczak I, Szanser M (2006) Response of soil micro- and mesofauna to diversity and quality of plant litter. Eur J Soil Biol 42:244–249
Jeffery S, Gardi C, Jones A, Montanarella L, Marmo L, Miko L, Ritz K, Peres G, Rombke J, van der Putten WH (eds) (2010) European atlas of soil biodiversity. European Commission, Publications Office of the European Union, Luxembourg
Jégou D, Capowiez Y, Cluzeau D (2001) Interactions between earthworm species in artificial soil cores assessed through the 3D reconstruction of the burrow systems. Geoderma 102:123–137
Kaiser C, Koranda M, Kitzler B, Fuchslueger L, Schnecker J, Schweiger P, Rasche F, Zechmeister-Boltenstern S, Sessitsch A, Richter A (2010) Belowground carbon allocation by trees drives seasonal patterns of extracellular enzyme activities by altering microbial community composition in a beech forest soil. New Philol 187:843–858
Kohyt J, Skubała P (2013) Communities of mites (Acari) in litter and soil under the invasive red oak (Quercus rubra L.) and native pedunculate oak (Q. robur L.). Biol Lett 50:111–124
Kooch Y (2012) Soil variability related to pit and mound, canopy cover and individual trees in a Hyrcanian Oriental Beech stand. PhD thesis, Tarbiat Modares University
Kooch Y, Tarighat FS, Hosseini SM (2017) Tree species effects on soil chemical, biochemical and biological features in mixed Caspian lowland forests. Trees 31:863–872
Korboulewsky N, Perez G, Chauvat M (2016) How tree diversity affects soil fauna diversity: a review. Soil Biol Biochem 94:94–106
Kuikman PJ, Van Veen JA (1989) Mineralization of nitrogen by protozoa activity in soil. Biol Ferti Soils 8:13–18
Lavelle P, Barois I, Blanchart E, Brown G, Brussaard L, Decaens T, Fragoso C, Jimenez JJ, Kajondo KK, Angeles Mzartinez MDL, Moreno A, Pashanasi B, Senapati B, Villenave C (1998) Earthworms as a resource in tropical agro ecosystems. Nat Resour 34:26–41
Lee JJ, Leedale GF, Bradbury PC (2000) An illustrated guide to the protozoa, 2nd edn. Society of Protozoologists, Lawrence
Li Q, Jiang Y, Liang W, Lou Y, Zhang E, Liang C (2010) Long-term effect of fertility management on the soil nematode community in vegetable production under greenhouse conditions. Appl Soil Ecol 46:111–118
Li N, Zhang XP, Zhang LM (2014) Macro-soil fauna guilds in Korean pine plantation forest and secondary forest. Chin J Appl Environ Biol 1:22–29
Liang WJ, Lou YL, Li Q, Zhong S, Zhang XK (2009) Nematode faunal response to long-term application of nitrogen fertilizer and organic manure in Northeast China. Soil Biol Biochem 41:883–890
Madhav PT, Jan WG, Imke K, Gerlinde BDD (2014) Interactions between microbial-feeding and predatory soil fauna trigger N2O emissions. Soil Biol Biochem 70:256–262
Maharning AR, Mills AAA, Adl SM (2009) Soil community changes during secondary succession to naturalized grasslands. Appl Soil Ecol 41:137–147
Mariappan V, Karthikairaj K, Isaiarasu L (2013) Relationship between earthworm abundance and soil quality of different cultivated lands in Rajapalayam, Tamilnadu. World Appl Sci J 27:1278–1281
Matute MM (2013) Soil nematodes of Brassica rapa: influence of temperature and pH. Adv Nat Sci 6:20–26. https://doi.org/10.3968/j.ans.1715787020130604.2858
Mayzlish E, Steinberger Y (2004) Effects of chemical inhibitors on soil protozoan dynamics in a desert ecosystem. Biol Fertil Soils 39:415–421
Mc Cune B, Mefford M (1999) Multivariate analysis of ecological data version 4.17. MJM Software, Gleneden Beach
McLaren JR, Turkington R (2010) Plant functional group identity differentially affects leaf and root decomposition. Glob Change Biol 16:3075–3084
Migge-Kleian S, McLean MA, Maerz JC, Heneghan L (2006) The influence of invasive earthworms on indigenous fauna in ecosystems previously uninhabited by earthworms. Biol Invasions 8:1275–1285
Milcu A, Partsch S, Scherber C, Weisser WW, Scheu S (2008) Earthworms and legumes control litter decomposition in a plant diversity gradient. Ecology 89:1872–1882
Moghimian N, Hosseini SM, Kooch Y, Zarei Darki B (2017) Impacts of land use/covers changes on soil microbial and enzyme activities. CATENA 157:407–414
Mohammadnezhad Kiasari S, Sagheb-Talebi K, Rahmani R, Ghasemi Chapi O (2009) Seasonal variation of earthworm abundances and biomass in natural forests and plantations (North of Iran). Casp J Environ Sci 7:87–98
Nardi F, Spinsanti G, Boore JL, Carapelli A, Dallai R, Frati F (2003) Hexapod origins: monophyletic or paraphyletic? Science 299:1887–1889
Paul D, Nongmaithem A, Jha LK (2011) Collembolan density and diversity in a forest and an agro ecosystem. Open J Soil Sci 1:54–60
Rahmani R (2000) Study of earthworm’s abundance and their relation with major forest types in Neka. PhD thesis of Forest Sciences, Tarbiat Modarres University
Rahmani R, Saleh-Rastin N (2000) Abundance, vertical distribution and seasonal changes in earthworm abundance of Oak-Hornbeam, Hornbeam and Beech forests, Caspian forests, Iran. Iran J Nat Resour 53:37–52
Rocha De Lima KD, Camara R, Chaer GM, Pereira MG, Silva De Resende A (2017) Soil fauna as bio-indicator of recovery of degraded areas in the Caatinga biome. Rev Caatinga 3:401–411
Rodríguez-Arrieta JA, Retana-Salazar AP (2010) Dynamics of soil Oribatids (Acari) in a tropical regeneration ecosystem of Costa Rica. Entomotropica 25:125–132
Rqnn RM, Griffiths BS, Young IM (2001) Protozoa, nematodes and N-mineralization across a prescribed soil textural gradient. Pedobiologia 45:481–495
Sabrina T, Hanafi MM, Nor Azwady AA, Mahmud TMM (2009) Earthworm populations and cast properties in the soils of oil palm plantations. J Soil Sci 13:29–42
Salamon JA, Schaefer M, Alphei J, Schmid B, Scheu S (2004) Effects of plant diversity on Collembola in an experimental grassland ecosystem. Oikos 106:51–60
Salehi A, Ghorbanzadeh N, Kahneh E (2013) Earthworm biomass and abundance, soil chemical and physical properties under different poplar plantations in the north of Iran. J For Sci 6:223–229
Sarlo M (2006) Individual tree species effect on earthworm biomass in a tropical plantation panama. Can J For Res 3:419–427
Schneider K, Renker C, Scheu S, Maraun M (2004) Feeding biology of oribatid mites: a minireview. Phytophaga 14:247–256
Sigurdsson BD, Gudleifsson BE (2013) Impact of afforestation on earthworm populations in Iceland. Icel Agric Sci 26:21–36
Šnajdr J, Cajthaml T, Valášková V, Merhautová V, Petránková M, Spetz P (2011) Transformation of Quercus petraea litter: successive changes in litter chemistry are reflected in differential enzyme activity and changes in the microbial community composition. FEMS Microbiol Ecol 75:291–303
Song M, Li X, Jing S, Lei L, Wang J, Wan S (2016) Responses of soil nematodes to water and nitrogen additions in old-field grassland. Appl Soil Ecol 102:53–60
Sun X, Zhang X, Zhang S, Dai G, Han S, Liang W (2013) Soil nematode responses to increases in nitrogen deposition and precipitation in a temperate forest. PLoS ONE 8(12):e82468
Suthar S (2012) Seasonal dynamics in earthworm density, casting activity and soil nutrient cycling under Bermuda grass (Cynodon dactylon) in semiarid tropics, India. Environmentalist 32:503–511
Taleshi SAR, Dhumal KN, Alipour A, Espahbodi K, Ghasemi O (2009) Impact of alder (Alnus subcordata) in fertility of forest soil. Res J Environ Sci 3:640–644
Tavakoli M, Kooch Y, Akbarinia M (2018) The effect of degraded and reclaimed forest areas on carbon dioxide gas emissions and soil carbon mineralization in West of Mazandaran. In: International conferences of climate change and dendrochronology in Caspian ecosystems, Sari, Iran
Uvarov AV (2009) Inter- and intraspecific interactions in lumbricid earthworms: their role for earthworm performance and ecosystem functioning. Pedobiologia 53:1–27
Vikram Reddy M, Kiran Kumar VP, Ravinder Reddy V, Balashouri P, Yule DF, Cogle AL, Jangawad LS (1995) Earthworm biomass response to soil management in semi-arid tropical Alfisols agroecosystems. Biol Fertil Soils 19:317–321
Wardle DA (2002) Communities and ecosystems linking aboveground and belowground components. Princeton University Press, Princeton
Wissuwa J, Salamon J, Frank T (2013) Oribatida (Acari) in grassy arable fallows are more affected by soil properties than habitat age and plant species. Eur J Soil Biol 59:8–14
Xu XN, Hirata E (2002) Forest floor mass and litter fall in Pinus luchuensis plantations with and without broad-leaved trees. For Ecol Manage 157:165–173
Xu GL, Kuster TM, Gunthardt-Goerg MS, Dobbertin M, Li MH (2012) Seasonal exposure to drought and air warming affects soil Collembola and Mites. PLoS ONE 7(8):e43102
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Kooch, Y., Tavakoli, M. & Akbarinia, M. Tree species could have substantial consequences on topsoil fauna: a feedback of land degradation/restoration. Eur J Forest Res 137, 793–805 (2018). https://doi.org/10.1007/s10342-018-1140-1
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DOI: https://doi.org/10.1007/s10342-018-1140-1